Systematic Optimization of Water Models Using Liquid/Vapor Surface Tension Data
In this work, we investigate whether experimental surface tension measurements, which are less sensitive to quantum and self-polarization corrections, are able to replace the usual reliance on the heat of vaporization as experimental reference data for fitting force field models of molecular liquids...
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| Published in | The journal of physical chemistry. B Vol. 123; no. 32; pp. 7061 - 7073 |
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| Main Authors | , , , |
| Format | Journal Article |
| Language | English |
| Published |
United States
American Chemical Society
15.08.2019
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| Subjects | |
| Online Access | Get full text |
| ISSN | 1520-6106 1520-5207 1520-5207 |
| DOI | 10.1021/acs.jpcb.9b05455 |
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| Abstract | In this work, we investigate whether experimental surface tension measurements, which are less sensitive to quantum and self-polarization corrections, are able to replace the usual reliance on the heat of vaporization as experimental reference data for fitting force field models of molecular liquids. To test this hypothesis, we develop the fitting protocol necessary to utilize surface tension measurements in the ForceBalance optimization procedure to determine revised parameters for both three-point and four-point water models TIP3P-ST and TIP4P-ST. We find that the incorporation of surface tension in the fit results in a rigid three-point model that reproduces the correct temperature of maximum density of water for the first time but also leads to overstructuring of the liquid and less accurate transport properties. The rigid four-point TIP4P-ST model is highly accurate for a broad range of thermodynamic and kinetic properties, with similar performance compared to recently developed four-point water models. The results show surface tension to be a useful fitting property in general, especially when self-polarization corrections or nuclear quantum corrections are not readily available for correcting the heat of vaporization as is the case for other molecular liquids. |
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| AbstractList | In this work, we investigate whether experimental surface tension measurements, which are less sensitive to quantum and self-polarization corrections, are able to replace the usual reliance on the heat of vaporization as experimental reference data for fitting force field models of molecular liquids. To test this hypothesis, we develop the fitting protocol necessary to utilize surface tension measurements in the ForceBalance optimization procedure to determine revised parameters for both three-point and four-point water models TIP3P-ST and TIP4P-ST. We find that the incorporation of surface tension in the fit results in a rigid three-point model that reproduces the correct temperature of maximum density of water for the first time but also leads to overstructuring of the liquid and less accurate transport properties. The rigid four-point TIP4P-ST model is highly accurate for a broad range of thermodynamic and kinetic properties, with similar performance compared to recently developed four-point water models. The results show surface tension to be a useful fitting property in general, especially when self-polarization corrections or nuclear quantum corrections are not readily available for correcting the heat of vaporization as is the case for other molecular liquids. In this work, we investigate whether experimental surface tension measurements, which are less sensitive to quantum and self-polarization corrections, are able to replace the usual reliance on the heat of vaporization as experimental reference data for fitting force field models of molecular liquids. To test this hypothesis, we develop the fitting protocol necessary to utilize surface tension measurements in the ForceBalance optimization procedure to determine revised parameters for both three-point and four-point water models TIP3P-ST and TIP4P-ST. We find that the incorporation of surface tension in the fit results in a rigid three-point model that reproduces the correct temperature of maximum density of water for the first time but also leads to overstructuring of the liquid and less accurate transport properties. The rigid four-point TIP4P-ST model is highly accurate for a broad range of thermodynamic and kinetic properties, with similar performance compared to recently developed four-point water models. The results show surface tension to be a useful fitting property in general, especially when self-polarization corrections or nuclear quantum corrections are not readily available for correcting the heat of vaporization as is the case for other molecular liquids.In this work, we investigate whether experimental surface tension measurements, which are less sensitive to quantum and self-polarization corrections, are able to replace the usual reliance on the heat of vaporization as experimental reference data for fitting force field models of molecular liquids. To test this hypothesis, we develop the fitting protocol necessary to utilize surface tension measurements in the ForceBalance optimization procedure to determine revised parameters for both three-point and four-point water models TIP3P-ST and TIP4P-ST. We find that the incorporation of surface tension in the fit results in a rigid three-point model that reproduces the correct temperature of maximum density of water for the first time but also leads to overstructuring of the liquid and less accurate transport properties. The rigid four-point TIP4P-ST model is highly accurate for a broad range of thermodynamic and kinetic properties, with similar performance compared to recently developed four-point water models. The results show surface tension to be a useful fitting property in general, especially when self-polarization corrections or nuclear quantum corrections are not readily available for correcting the heat of vaporization as is the case for other molecular liquids. |
| Author | Head-Gordon, Teresa Wang, Lee-Ping Qiu, Yudong Nerenberg, Paul S |
| AuthorAffiliation | Pitzer Theory Center and Departments of Chemistry, Bioengineering and Chemical and Biomolecular Engineering Departments of Physics & Astronomy and Biological Sciences Chemistry Department |
| AuthorAffiliation_xml | – name: Departments of Physics & Astronomy and Biological Sciences – name: Chemistry Department – name: Pitzer Theory Center and Departments of Chemistry, Bioengineering and Chemical and Biomolecular Engineering |
| Author_xml | – sequence: 1 givenname: Yudong orcidid: 0000-0003-4345-8356 surname: Qiu fullname: Qiu, Yudong organization: Chemistry Department – sequence: 2 givenname: Paul S orcidid: 0000-0002-9730-6983 surname: Nerenberg fullname: Nerenberg, Paul S organization: Departments of Physics & Astronomy and Biological Sciences – sequence: 3 givenname: Teresa orcidid: 0000-0003-0025-8987 surname: Head-Gordon fullname: Head-Gordon, Teresa organization: Pitzer Theory Center and Departments of Chemistry, Bioengineering and Chemical and Biomolecular Engineering – sequence: 4 givenname: Lee-Ping orcidid: 0000-0003-3072-9946 surname: Wang fullname: Wang, Lee-Ping email: leeping@ucdavis.edu organization: Chemistry Department |
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| Title | Systematic Optimization of Water Models Using Liquid/Vapor Surface Tension Data |
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